Alfredo Nicosia

Novel Adenovirus-Based Vaccines Induce Broad and Sustained T Cell Responses to HCV in Man

An adenoviral HCV vaccine induces antiviral T cell responses in human volunteers. Hepatitis Hide and Seek Like venture capitalists and Wall Street bankers, patients receiving results of their blood work don’t like surprises, and more than money is at stake. Because infections caused by the hepatitis C virus (HCV) frequently are asymptomatic, patients might not know they’ve been infected: Symptoms don’t usually appear until irreversible liver scarring has occurred, which may cause cirrhosis, liver failure, or cancer. Even if infection is caught early, current therapies to combat this stealth virus have serious side effects, and there is no vaccine to prevent or treat HCV infection. Now, Barnes et al. demonstrate that vaccines developed with adenoviral vectors can induce broad and sustained immune responses to HCV in humans. Adenoviral vectors have shown promise in vaccine trials in animal models; however, preexisting immunity to common serotypes in humans has limited their use. In a phase 1 clinical trial, Barnes et al. vaccinated healthy subjects with two rare serotype adenoviral vectors that expressed an HCV protein. Both the human and the chimp adenoviral vaccinations elicited HCV-specific immune responses in the recipients that responded to multiple HCV antigens, were sustained for at least a year with boost, and elicited memory responses. And the researchers got a surprise they liked: Vaccination primed T cells to respond to multiple HCV strains at a level consistent with protective immunity. Further trials will be needed to confirm protective or therapeutic roles in HCV-infected individuals. Currently, no vaccine exists for hepatitis C virus (HCV), a major pathogen thought to infect 170 million people globally. Many studies suggest that host T cell responses are critical for spontaneous resolution of disease, and preclinical studies have indicated a requirement for T cells in protection against challenge. We aimed to elicit HCV-specific T cells with the potential for protection using a recombinant adenoviral vector strategy in a phase 1 study of healthy human volunteers. Two adenoviral vectors expressing NS proteins from HCV genotype 1B were constructed based on rare serotypes [human adenovirus 6 (Ad6) and chimpanzee adenovirus 3 (ChAd3)]. Both vectors primed T cell responses against HCV proteins; these T cell responses targeted multiple proteins and were capable of recognizing heterologous strains (genotypes 1A and 3A). HCV-specific T cells consisted of both CD4+ and CD8+ T cell subsets; secreted interleukin-2, interferon-γ, and tumor necrosis factor–α; and could be sustained for at least a year after boosting with the heterologous adenoviral vector. Studies using major histocompatibility complex peptide tetramers revealed long-lived central and effector memory pools that retained polyfunctionality and proliferative capacity. These data indicate that an adenoviral vector strategy can induce sustained T cell responses of a magnitude and quality associated with protective immunity and open the way for studies of prophylactic and therapeutic vaccines for HCV.

A general strategy to identify mimotopes of pathological antigens using only random peptide libraries and human sera.

A strategy to identify disease‐specific epitopes from phage‐displayed random peptide libraries using human sera is described. Peptides on phage (phagotopes) that react with antibodies present in patient sera are purified from > 10(7) different sequences by affinity selection and immunological screening of plaques. Disease‐specific phagotopes can be identified out of this pool through an ‘antigen independent’ procedure which avails itself only of patient and normal human sera. Using this strategy, we have selected antigenic mimics (mimotopes) of two different epitopes from the human hepatitis B virus envelope protein (HBsAg). We could show that a humoral response to these mimotopes is widespread in the immunized population, suggesting that the strategy identifies phagotopes that have a potential role as diagnostic reagents. Immunization of mice with the selected phagotopes elicited a strong specific response against the HBsAg. These results open new inroads into disease‐related epitope discovery and provide the potential for vaccine development without a requirement for the use of, or even information about, the aetiological agent or its antigens.

Protective CD8 + T-cell immunity to human malaria induced by chimpanzee adenovirus-MVA immunisation

Induction of antigen-specific CD8+ T cells offers the prospect of immunization against many infectious diseases, but no subunit vaccine has induced CD8+ T cells that correlate with efficacy in humans. Here we demonstrate that a replication-deficient chimpanzee adenovirus vector followed by a modified vaccinia virus Ankara booster induces exceptionally high frequency T-cell responses (median >2400 SFC/106 peripheral blood mononuclear cells) to the liver-stage Plasmodium falciparum malaria antigen ME-TRAP. It induces sterile protective efficacy against heterologous strain sporozoites in three vaccinees (3/14, 21%), and delays time to patency through substantial reduction of liver-stage parasite burden in five more (5/14, 36%), P=0.008 compared with controls. The frequency of monofunctional interferon-γ-producing CD8+ T cells, but not antibodies, correlates with sterile protection and delay in time to patency (Pcorrected=0.005). Vaccine-induced CD8+ T cells provide protection against human malaria, suggesting that a major limitation of previous vaccination approaches has been the insufficient magnitude of induced T cells.

Prime-boost vectored malaria vaccines: progress and prospects.

The difficulty of inducing protective immunity through antibodies against sporozoites led to efforts to assess vectored vaccines as a means of inducing protective T cell immunity against the malaria liver-stage parasite. Although DNA vectored vaccines used alone were poorly immunogenic and not protective, high levels of parasite clearance in the liver has been achieved with viral vectored vaccines used in heterologous prime-boost regimes. Such vectored vaccination regimes represent one of only two approaches that have induced repeatable partial efficacy in human P. falciparum subunit vaccine trials. Interestingly, vectors expressing the TRAP antigen have been consistently been more immunogenic and protective than vectors expressing the circumsporozoite protein in human trials. However, sterile protection requires induction of very potent T cell responses that are currently only achievable with heterologous prime-boost regimes. Recently, simian adenoviruses have been assessed as priming agents in Adenovirus-MVA regimes in both phase I and phase IIa trials in the UK, based on very promising pre-clinical results showing better immunogenicity and efficacy than previous prime-boost regimes. The same vectors are also being assessed clinically expressing blood-stage antigens, attempting to induce both protective antibodies and T cells as recently demonstrated in murine efficacy studies. These viral vectors now provide a major option for inclusion in a high efficacy multi-stage malaria vaccine that should achieve deployable levels of efficacy in endemic settings.

Vaccine vectors derived from a large collection of simian adenoviruses induce potent cellular immunity across multiple species.

Simian adenoviruses screened from wild-derived candidates can prime T cell responses in man and may serve as new vaccine vector candidates. Deepening the Talent Pool Whether you’re talking about drafting for a professional sports team or hiring new lab staff, increasing the number of candidates improves your chances of the truly exceptional find. When it comes to vaccine vectors, the pool of human adenovirus candidates has been quite shallow. Although certain vectors are highly immunogenic in animal models, they can be neutralized by preexisting antibodies in humans. Yet, Colloca et al. show that viruses that are more rare in humans and are thus less likely to be neutralized are not as immunogenic. Therefore, the authors deepened the vector pool by isolating more than 1000 adenovirus strains from chimpanzees. They identified vectors that grew in human cells and were not neutralized by human sera and prevented them from replicating. As with human adenoviral vectors, different simian vectors induced either more or less potent immune responses in mice. The more potent of these vectors were also immunogenic in humans. These chimp adenoviral vectors provide such embarrassment of riches that different vectors could be used for each vaccine target, lowering the chances of subsequent cross-reactive neutralization. Thus, these vectors serve as prime candidates for future vaccine development. Replication-defective adenovirus vectors based on human serotype 5 (Ad5) induce protective immune responses against diverse pathogens and cancer in animal models, as well as elicit robust and sustained cellular immunity in humans. However, most humans have neutralizing antibodies to Ad5, which can impair the immunological potency of such vaccines. Here, we show that rare serotypes of human adenoviruses, which should not be neutralized in most humans, are far less potent as vaccine vectors than Ad5 in mice and nonhuman primates, casting doubt on their potential efficacy in humans. To identify novel vaccine carriers suitable for vaccine delivery in humans, we isolated and sequenced more than 1000 adenovirus strains from chimpanzees (ChAd). Replication-defective vectors were generated from a subset of these ChAd serotypes and screened to determine whether they were neutralized by human sera and able to grow in human cell lines. We then ranked these ChAd vectors by immunological potency and found up to a thousandfold variation in potency for CD8+ T cell induction in mice. These ChAd vectors were safe and immunologically potent in phase 1 clinical trials, thereby validating our screening approach. These data suggest that the ChAd vectors developed here represent a large collection of non–cross-reactive, potent vectors that may be exploited for the development of new vaccines.

Towards a solution for hepatitis C virus hypervariability: mimotopes of the hypervariable region 1 can induce antibodies cross-reacting with a large number of viral variants

The hypervariable region 1 (HVR1) of the putative envelope protein E2 of hepatitis C virus (HCV) is the most variable antigenic fragment in the whole viral genome and is mainly responsible for the large inter‐and intra‐individual heterogeneity of the infecting virus. It contains a principal neutralization epitope and has been proposed as the major player in the mechanism of escape from host immune response. Since anti‐HVR1 antibodies are the only species shown to possess protective activity up to date, developing an effective prevention therapy is a very difficult task. We have approached the problem of HVR1 variability by deriving a consensus profile from >200 HVR1 sequences from different viral isolates and used it as a template to generate a vast repertoire of synthetic HVR1 surrogates displayed on M13 bacteriophage. This library was affinity selected using many different sera from infected patients. Phages were identified which react very frequently with patients‘ sera and bind serum antibodies that cross‐react with a large panel of HVR1 peptides derived from natural HCV variants. When injected into experimental animals, the ‘mimotopes’ with the highest cross‐reactivity induced antibodies which recognized the same panel of natural HVR1 variants. In these mimotopes we identified a sequence pattern responsible for the observed cross‐reactivity. These data may hold the key for future development of a prophylactic vaccine against HCV.

A Monovalent Chimpanzee Adenovirus Ebola Vaccine Boosted with MVA

BACKGROUND The West African outbreak of Ebola virus disease that peaked in 2014 has caused more than 11,000 deaths. The development of an effective Ebola vaccine is a priority for control of a future outbreak. METHODS In this phase 1 study, we administered a single dose of the chimpanzee adenovirus 3 (ChAd3) vaccine encoding the surface glycoprotein of Zaire ebolavirus (ZEBOV) to 60 healthy adult volunteers in Oxford, United Kingdom. The vaccine was administered in three dose levels--1×10(10) viral particles, 2.5×10(10) viral particles, and 5×10(10) viral particles--with 20 participants in each group. We then assessed the effect of adding a booster dose of a modified vaccinia Ankara (MVA) strain, encoding the same Ebola virus glycoprotein, in 30 of the 60 participants and evaluated a reduced prime-boost interval in another 16 participants. We also compared antibody responses to inactivated whole Ebola virus virions and neutralizing antibody activity with those observed in phase 1 studies of a recombinant vesicular stomatitis virus-based vaccine expressing a ZEBOV glycoprotein (rVSV-ZEBOV) to determine relative potency and assess durability. RESULTS No safety concerns were identified at any of the dose levels studied. Four weeks after immunization with the ChAd3 vaccine, ZEBOV-specific antibody responses were similar to those induced by rVSV-ZEBOV vaccination, with a geometric mean titer of 752 and 921, respectively. ZEBOV neutralization activity was also similar with the two vaccines (geometric mean titer, 14.9 and 22.2, respectively). Boosting with the MVA vector increased virus-specific antibodies by a factor of 12 (geometric mean titer, 9007) and increased glycoprotein-specific CD8+ T cells by a factor of 5. Significant increases in neutralizing antibodies were seen after boosting in all 30 participants (geometric mean titer, 139; P<0.001). Virus-specific antibody responses in participants primed with ChAd3 remained positive 6 months after vaccination (geometric mean titer, 758) but were significantly higher in those who had received the MVA booster (geometric mean titer, 1750; P<0.001). CONCLUSIONS The ChAd3 vaccine boosted with MVA elicited B-cell and T-cell immune responses to ZEBOV that were superior to those induced by the ChAd3 vaccine alone. (Funded by the Wellcome Trust and others; ClinicalTrials.gov number, NCT02240875.).

LFB3, a heterodimer-forming homeoprotein of the LFB1 family, is expressed in specialized epithelia.

We have cloned and characterized a mouse cDNA coding for LFB3, a DNA binding protein containing an extra‐large homeodomain. The first 315 amino acids of LFB3 are highly homologous to the DNA binding domain of LFB1, a regulatory protein involved in the expression of several liver‐specific genes. LFB3 is a transcriptional activator which binds to DNA as a dimer and forms heterodimers with LFB1 both in vitro and in vivo. However, LFB3 expression seems not to be directly correlated with the liver‐specific phenotype, since it is detected in dedifferentiated hepatoma cell lines which express neither LFB1 nor several liver‐specific genes. LFB3 expression starts before that of LFB1 during mouse and rat development, and is strongly increased upon retinoic acid induced differentiation of F9 embryonic carcinoma cells. LFB3 and LFB1 are expressed in the epithelial component of many organs of endodermal and mesodermal origin, suggesting that they may play a more general role associated with the differentiation of specialized epithelia.

Identification of biologically active peptides using random libraries displayed on phage

The construction of new and increasingly diverse libraries, as well as the implementation of more powerful selection schemes, has led to the identification of linear peptides that mimic complex epitopes. Phage display techniques are allowing the selection of disease-related peptides, which reproduce the antigenic and immunogenic properties of natural antigens, using whole sera from patients. The range of applications of phage technology has been extended to include the search for peptides binding to molecules other than antibodies, such as cell receptors and enzymes.

Two different liver-specific factors stimulate in vitro transcription from the human alpha 1-antitrypsin promoter.

The region from −137 to −2 of the human alpha 1‐antitrypsin (alpha 1AT) promoter directs liver‐specific in vitro transcription. Two cis‐acting elements, A and B, have been identified within this segment by site‐directed mutagenesis. Competition with synthetic oligonucleotides corresponding either to the A or to the B sequence inhibits transcription from the wild‐type promoter in vitro. Cis‐linked A and B elements mediate liver‐specific transcription from a truncated HSV‐TK promoter in vitro. Five different proteins, LF‐A1, LF‐A2, LF‐B1, LF‐B2 and LF‐C, bind to the alpha 1AT promoter in liver extracts. LF‐A1 and LF‐B1 are positive transcriptional factors which bind to the A and B elements respectively. Their absence in spleen provides an explanation for the liver specificity of transcription. A protein similar to LF‐B2 is present in spleen. Binding of LF‐B1 and LF‐B2 to the alpha 1AT promoter is mutually exclusive, suggesting that LF‐B2 might be a repressor.